KR20020073154A - Selective Olefin Oligomerization - Google Patents

Abstract

The present invention relates to an isooctane-rich gasoline blended fraction produced in reactor (5) by dimerization of isobutylene with tertiary butyl alcohol modifiers and lower alkanes diluents. Conveniently, the isobutylene is produced by dehydrated tertiary butyl alcohol in the dehydration zone (2).

Description

Selective Olefin Oligomerization

Oligomerization with an acid catalyst of olefins such as isobutylene is a known reaction.

As disclosed in US Pat. No. 3,760,026, many catalysts are known for this reaction, including cold sulfonic acid; Phosphoric acid on diatomaceous earth; Silicon / aluminum, sometimes promoted with Ni, Co, Fe, Pt or Pd; Active substances such as activated natural clay and ZnO; Metal phosphates such as phosphate of iron (III) and cerium supported on a carrier such as optionally activated carbon; Bauxite; Activated carbon alone and in combination with metal halogens such as TiCl ₂ ; Heteropoly acids such as silicotungstic acid and phosphomolybdenic acid on silica gel; BF ₃ H ₃ PO ₄ and BF ₃ HPO ₃ ; Dihydroxyfluoroboric acid; Fluorides or oxyfluorides and HF of S, Se, N, P, Mo, Te, W, V and Si having a boiling point of 300 ° C. or lower; BF ₃ dimethyl ether complex; BF ₃ hydrocarbon complexes; BF ₃ SO ₂ ; AlCl ₃ is used in combination with cocatalysts such as dimethyl ether, HCl and nitromethane. Such catalysts and dimerization methods and operating conditions are known in the art.

Particularly preferred catalysts are sulfonic acid-type ion exchange resins such as Amberlyst A-15. US 4,447,668 discloses isobutylene dimerization using A-15 with methyl t-butyl ether as solvent.

US Patent No. 5,877,372 discloses the selective dimerization of isobutylene using sulfonic acid resin catalysts, tertiary butanol selectivity enhancing modifiers and isooctane diluents.

US 4,100,220 discloses dimerization of isobutylene using sulfonic acid resin catalysts and tertiary butanol selectivity enhancing modifiers. Dimerization Reaction A small amount of butane is seen in the feed.

Considerations related to isobutylene dimerization are the requirement of removing substantial heat of the reaction and maintaining high selectivity for the dimer product. The present invention provides a way in which this object can be achieved.

FIELD OF THE INVENTION The present invention relates to the selective dimerization of isobutylene, and more particularly to the dimerization using C ₃ and / or C ₄ alkanes as dimerization solvents while supplying tertiary butanol as a selectivity enhancing modifier during the dimerization reaction. .

The accompanying drawings are schematic diagrams of particularly preferred embodiments of the present invention.

According to the present invention there is provided a method for dimerizing isobutylene in the presence of C ₃ and / or C ₄ , preferably C ₄ alkanes as an effective amount and diluent for enhancing selectivity of tertiary butanol. In a particularly preferred embodiment, tertiary butanol derived from the oxirane propylene oxide / tertiary butanol process is used as starting material and isooctane produced by hydrogenation of the dimer is the final product.

Referring to the figure and the method presented in the figure, the tertiary butanol product from the Oxirane process produces a reaction starting material. The tertiary butanol is charged to hydrogenation zone 2 along the line 1 where the tertiary butanol is dehydrated according to a known process to produce isobutylene, and water is removed via line 3 from zone 2.

Part of the tertiary butanol is sent via line 4 to be used as a selectivity enhancing modifier in the dimerization of isobutylene produced in Zone 5, described below.

The product isobutylene is removed from zone 2 via line 6 and sent to dimerization zone 5 where the isobutylene dimerizes with high selectivity to yield diisobutylene. In order to achieve high selectivity of dimerization in Zone 5, it is important to carry out the process of feeding selectivity enhancing effective amounts of tertiary butanol via lines 4 and 10 and butanes as dimerization diluent via line 10.

The raw material composition supplied to zone 5 is an effective amount to enhance the selectivity of tertiary butanol, generally 1 to 30% by weight, and an amount effective to remove heat and reduce isobutylene concentration to a level at which optimum selectivity, such as 97%, can be achieved. Alkanes diluent, generally 30 to 80% by weight of alkanes, based on the total feed of region 5.

The alkane diluent used for the dimerization is preferably isobutane or normal butane or any proportion thereof and may be added via line 7 as needed. Propane may also be used.

In zone 5, the isobutylene containing raw material is a solid dimer catalyst, preferably a sulfonic acid resin catalyst, such as Amberlyst A-15 (Rohm), under dimerization reaction conditions in which excellent high reaction selectivity for the dimer can be achieved. & Hass). In addition, generally a small amount of trimers in Zone 5 is produced, for example in an amount of up to 10% of the converted isobutylene.

The reaction mixture from zone 5 comprising tertiary butyl alcohol, alkane diluent, unreacted isobutylene and isobutylene dimers and trimers passes through separation zone 9 via line 8, in which zone unreacted iso The stream comprising butylenes, alkane diluents, and tertiary butyl alcohol and small amounts of C ₈ product are separated in a conventional manner and reintroduced to dimerization zone 5 via line 10. Small-scale purification of this refeed stream may be necessary to maintain tertiary butyl alcohol levels and this is provided via line 15. This purge is reintroduced into zone 2 to recover the tertiary butyl alcohol, alkanes and isobutylene values. The higher boiling stream comprising alkanes, isobutylene dimers and trimers is passed through line 11 to hydrogenation zone 12 where the isobutylene polymer product is hydrogenated to produce a polymer gasoline composition. Hydrogen is introduced via line 13.

The product stream from zone 12, which mainly contains isooctane and some isododecane, is removed via line 14 to make the product suitable for high octane gasoline pool blending compositions.

The production of tertiary butyl alcohol by the oxirane process is known and widely practiced in the industrial range. See, eg, US Patent No. 3,351,635.

Similarly, methods of dehydrating tertiary butanol to form isobutylene are also known. See, for example, US Pat. Nos. 5,625,109, 3,510,538, 4,165,343, and 4,155,945.

Dimerization of isobutylene according to the present invention includes a variety of novel properties. In a first example, tertiary butanol is used as a selectivity enhancing modifier and thus substantially improves the reaction selectivity for dimers over methods that do not use such modifiers.

Secondly, C ₃ -C ₄ alkanes, preferably butanes, are used as diluents to further reduce reaction isobutylene concentrations, thereby further improving reaction selectivity and helping to remove heat of reaction.

In general, known oligomerization catalysts and conditions can be used in the oligomerization step. Suitable conditions include a wide temperature range of 0 to 200 ° C., preferably a temperature of 10 to 100 ° C. and a pressure sufficient to maintain the liquid state, for example at least 50 psig, such as 50-500 psig.

Known dimerization catalysts can be used, including those disclosed in the prior art, for example, in US Pat. No. 3,760,026. Sulphonic acid type ion exchange resins such as Amberlyst A-15, Dowex 50 and the like are particularly preferred.

A feature of the present invention is the use of tertiary butanol as a selectivity enhancing modifier of olefin dimerization.

The amount of modifier used is at least 1% by weight, preferably 5 to 15% by weight relative to the total weight of the olefin and the modifier and diluent in the reaction mixture.

By carrying out oligomerization with tertiary butyl alcohol and lower alkanes, reaction selectivity for at least 90% of diisobutylene is achieved for the isobutylene being converted. The residual reaction product is essentially trimer and little or no higher polymer is formed.

The reaction mixture passes from oligomerization zone 5 to zone 9 which is a regionally suitable distillation zone. Unreacted isobutylene, alkane diluent and tertiary butyl alcohol modifier remaining in the mixture are separated and reintroduced into zone 5 via line 10. Zone 5 may require some dehydration of tertiary butyl alcohol and zone 9 may have a loss of tertiary butyl alcohol, so supply of tertiary butyl alcohol to the system via line 4 is required.

Tertiary butyl alcohol is consumed or produced in Zone 5 depending on equilibrium with isobutylene and water. It is advantageous to operate the raw material in near-equilibrium conditions where the net change in tertiary butyl alcohol is near zero.

The isobutylene polymer product passes through line 11 to hydrogenation zone 12 where the unsaturated polymer is hydrogenated according to known processes to produce a saturated product, mainly isooctane. Hydrogen is introduced via line 13.

The product from zone 12 can be removed via line 14 and sent directly to the gasoline blending pool and this stream essentially contains high octane gasoline blended hydrocarbons.

The following examples illustrate the invention.

Referring to the accompanying drawings, tertiary butanol derived from the oxirane propylene oxide / tertiary butanol process forms the raw material of the system of the present invention. The raw material comprises about 94% by weight tertiary butanol and residues, mainly water and acetone.

About 250,000 lbs / hr of tertiary butanol was fed via line 1 to dewatering zone 2, where the tertiary butanol was dewatered at about 371 ° C. and 200 psig using an aluminum dehydration catalyst. The water produced by dehydration and the input with the raw material were removed via line 3 at a rate of 60,000 lbs / hr. Dewatering zone 2 via line 6 at a rate of 190,000 lbs / hr, product isobutylene stream comprising 96.5 wt% isobutylene, 1.0 wt% tertiary butanol, 0.02 wt% water, 1.3 wt% acetone and 1.18 wt% other From dimerization zone 5 through. In addition, a portion of the tertiary butanol by the oxirane method was passed through line 4 to zone 5 at a rate of 20 lbs / hr (this pass is intermittent as needed), 31.8 wt.% Isobutylene, butane 52.3 Regenerated isobutylene, butane and tertiary butyl alcohol streams from zone 9 comprising wt.%, 5.6 wt.% Tertiary butyl alcohol and 2.7 wt.% C ₈ and C ₁₂ isoalkanes, were fed Passed to area 5. The composition of the butane was 10% isobutane and 90% normal butane.

The feed stream reacted through Zone 5 had a composition of 48% isobutylene, 4.5% tertiary butanol, 44% butane, 0.3% water, 2% high alkanes and 1.2% other. Zone 5 is a reactor packed with an A-15 sulfonic acid resin catalyst and the liquid stock was reacted with the catalyst at 190 ° C. and 300 psig at a liquid hourly space velocity of 6 hr ⁻ .

The reaction mixture was removed from zone 5 via line 8 and passed through separation zone 9 to distill lighter material away to zone 5 via line 10 as described above at 60 ° C. and 50 psig. The purified stream in the amount of 6650 lbs / hr was removed via line 15.

The bottom isobutylene dimer mixture comprising 95% by weight diisobutylene, 5% by weight higher isobutylene oligomer and traces of other materials was passed through the line 11 to hydrogenation zone 12 at a rate of 183350 lbs / hr, In the isobutylene polymer was dehydrated to produce isoalkanes. Hydrogen was introduced via line 13 at a rate of 11,500 lbs / hr, using a carbon-supported Pd hydrogenation catalyst and using a space time velocity at 150 ° C., 200 psig and 5 hr ⁻ .

The hydrogenation can be carried out using various catalysts and reaction conditions in accordance with known processes. Although Pd catalysts were used in the above examples, various other known hydrogenation catalysts may also be used. In order to adjust the heat of hydrogenation reaction, it is preferable to use the raw material regeneration rate of about 3: 1 weight ratio for cooling regeneration.

The hydrogenation reaction product mixture was removed from zone 12 and recovered via line 14 at a rate of 185,819 lbs / hr. Surplus H ₂ was reintroduced into Region 12.

The overall selectivity for isooctane in this system was about 95% based on the tertiary butanol converted. In comparison, the total selectivity without using both the tertiary butanol modifier or butane diluent is only 30%.

Claims (3)

A method of selectively oligomerizing isobutylene to form a dimer, wherein the C ₃ -C ₄ alkane diluent and the oligomerization selectivity of the dimer are sufficient to enhance the oligomerization selectivity of the dimer and to absorb the heat of reaction. And oligomerizing the isobutylene in the presence of a sufficient amount of tertiary butanol for promotion. Oligomerizing isobutylene into dimers with at least 90% selectivity by sulfonic acid resin catalyst, tertiary butanol selectivity enhancing modifier and C ₄ alkanes diluent, and hydrogenating the oligomerization product to produce predominantly isooctane A method of producing a high-octane gasoline blending mixture comprising mainly isooctane. The method of claim 1, wherein the isobutylene is produced by dehydration of tertiary butanol.